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By NASA
5 Min Read ‘Current’ Events: NASA and USGS Find a New Way to Measure River Flows
The River Observing System (RiOS) tracking the motion of water surface features from above a section of the Sacramento River in Northern California in 2023. Credits: NASA/USGS/Joe Adams and Chris Gazoorian A team of scientists and engineers at NASA and the U.S. Geological Survey (USGS) collaborated to see if a small piloted drone, equipped with a specialized payload, could help create detailed maps of how fast water is flowing. Rivers supply fresh water to our communities and farms, provide homes for a variety of creatures, transport people and goods, and generate electricity. But river flows can also carry pollutants downstream or suddenly surge, posing dangers to people, wildlife, and property. As NASA continues its ongoing commitment to better understand our home planet, researchers are working to answer the question of how do we stay in-the-know about where and how quickly river flows change?
NASA and USGS scientists have teamed up to create an instrument package – about the size of a gallon of milk – called the River Observing System (RiOS). It features thermal and visible cameras for tracking the motion of water surface features, a laser to measure altitude, navigation sensors, an onboard computer, and a wireless communications system. In 2023, researchers took RiOS into the field for testing along a section of the Sacramento River in Northern California, and plan to return for a third and final field test in the fall of 2024.
The River Observing System (RiOS) tracking the motion of water surface features from above a section of the Sacramento River in Northern California in 2023. “Deploying RiOS above a river to evaluate the system’s performance in a real-world setting is incredibly important,” said Carl Legleiter, USGS principal investigator of the joint NASA-USGS StreamFlow project. “During these test flights we demonstrated that the onboard payload can be used to make calculations – do the analysis – in nearly real-time, while the drone is flying above the river. This was one of our top-tier goals: to enable minimal latency between the time we acquire images and when we have detailed information on current speeds and flow patterns within the river.”
To realize this vision for onboard computing, the team uses open-source software, combined with their own code, to produce maps of water surface velocities, or flow field, from a series of images taken over time.
“You might think that we need to be able to see discrete, physical objects – like sticks or silt or other debris as they move downstream – to estimate the flow velocity, but that’s not always the case, nor is it always possible,” said Legleiter. “Using a highly-sensitive infrared camera, we instead detect the movement of subtle differences in the temperature of water carried downstream.”
Those same tiny temperature differences also appear wherever there are undulations – like at the boundary between the air and the water or ice below. Knowing this, NASA members of the StreamFlow team used this phenomenon to their advantage when developing methods for possible future landed planetary missions to navigate at distant and hard-to-see environments, including Europa, the icy moon orbiting Jupiter.
Our technology can precisely track the static surface of icy terrain while flying over it, or a moving surface, like water, while hovering above it to keep the spacecraft safe while gathering valuable data
uland wong
Co-investigator and NASA lead of the StreamFlow Project
“Icy surfaces present challenging visual conditions such as lack of contrast,” said Uland Wong, co-investigator and NASA lead of the StreamFlow project at NASA’s Ames Research Center in California’s Silicon Valley. “Our technology can precisely track the static surface of icy terrain while flying over it, or a moving surface, like water, while hovering above it to keep the spacecraft safe while gathering valuable data.”
To prepare for the Sacramento River field tests, the NASA team built a robotics simulator to run thousands of virtual drone flights over the Sacramento River test site using flow fields modeled by USGS. These simulations are helping the team create intelligent software capable of selecting the best routes for the drone to fly and ensuring efficient use of limited battery power.
The next step in the partnership is for NASA to develop techniques for making the system more autonomous. The researchers want to use calculations of river flows – performed onboard in real time – to guide where the drone should fly next.
“Does the drone drop down to get better resolution data about a particular location or stay high and capture a wide-angle view,” posed Wong. “If it identifies areas that are flowing particularly fast or slow, could the drone more quickly detect areas of flooding?”
The USGS currently operates an extensive network of thousands of automated stream gauges and fixed cameras installed on bridges and riverbanks to monitor river flows in real-time across the country.
“Drones could enable us to make measurements in so many more areas, potentially allowing our network to be larger, more robust, and safer for our technicians to monitor and maintain,” said Paul Kinzel, StreamFlow co-investigator at USGS. “Drones could help keep our people and equipment out of harm’s way in addition to telling us how the environment is changing over time in as many locations as possible.”
A drone with the StreamFlow thermal mapping payload flying above the Sacramento River in Northern California.NASA/Massimo Vespignani For more information about how NASA improves life on Earth through climate and technological innovations, visit:
http://www.nasa.gov/earth
The StreamFlow project is a collaboration between researchers with the USGS’s Hydrologic Remote Sensing Branch, Unmanned Aircraft Systems engineers with the USGS National Innovation Center, and scientists in the Intelligent Robotics Group at NASA Ames. The Streamflow payload concept was demonstrated through research initially seeded by a grant from the USGS National Innovation Center and is now supported by NASA’s Advanced Information Systems Technology program, which is managed by the agency’s Earth Science Technology Office. The field tests were conducted in collaboration with the National Oceanographic and Atmospheric Administration (NOAA) Southwest Fisheries Science Center, which helped collect direct field measurements of the river’s flow velocity and granted access to the field site, which is owned by the Nature Conservancy.
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Last Updated Aug 05, 2024 Related Terms
Earth Science Division Ames Research Center Applied Sciences Program Drones & You General USGS (United States Geological Survey) Keep Exploring Discover More Topics From NASA
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By NASA
5 min read
Preparations for Next Moonwalk Simulations Underway (and Underwater)
Perseverance captured this mosaic looking downstream of the dune-filled Neretva Vallis river channel on May 17. The channel fed Jezero Crater with fresh water billions of years ago.NASA/JPL-Caltech/ASU/MSSS Originally thought of as little more than a route clear of rover-slowing boulders, Neretva Vallis has provided a bounty of geologic options for the science team.
After detouring through a dune field to avoid wheel-rattling boulders, NASA’s Perseverance Mars rover reached its latest area of scientific interest on June 9. The route change not only shortened the estimated drive time to reach that area — nicknamed “Bright Angel” — by several weeks, but also gave the science team an opportunity to find exciting geologic features in an ancient river channel.
Perseverance is in the later stages of its fourth science campaign, looking for evidence of carbonate and olivine deposits in the “Margin Unit,” an area along the inside of Jezero Crater’s rim. Located at the base of the northern channel wall, Bright Angel features rocky light-toned outcrops that may represent either ancient rock exposed by river erosion or sediments that filled the channel. The team hopes to find rocks different from those in the carbonate-and-olivine-rich Margin Unit and gather more clues about Jezero’s history.
Stitched together from 18 images taken by NASA’s Perseverance rover, this mosaic shows a boulder field on “Mount Washburn” on May 27. Intrigued by the diversity of textures and chemical composition in the light-toned boulder at center, the rover’s science team nicknamed the rock “Atoko Point.”NASA/JPL-Caltech/ASU/MSSS To get to Bright Angel, the rover drove on a ridge along the Neretva Vallis river channel, which billions of years ago carried a large amount of the water that flowed into Jezero Crater. “We started paralleling the channel in late January and were making pretty good progress, but then the boulders became bigger and more numerous,” said Evan Graser, Perseverance’s deputy strategic route planner lead at NASA’s Jet Propulsion Laboratory in Southern California. “What had been drives averaging over a hundred meters per Martian day went down to only tens of meters. It was frustrating.”
Channel Surfing
In rough terrain, Evan and his team use rover imagery to plan drives of about 100 feet (30 meters) at a time. To go farther on any given Martian day, or sol, planners rely on Perseverance’s auto-navigation, or AutoNav, system to take over. But as the rocks became more plentiful, AutoNav would, more times than not, determine the going was not to its liking and stop, dimming the prospects of a timely arrival at Bright Angel. The team held out hope, however, knowing they might find success cutting across a quarter-mile (400-meter) dune field in the river channel.
NASA’s Perseverance rover was traveling in the ancient Neretva Vallis river channel when it captured this view of an area of scientific interest named “Bright Angel” — the light-toned area in the distance at right — with one of its navigation cameras on June 6.NASA/JPL-Caltech “We had been eyeing the river channel just to the north as we went, hoping to find a section where the dunes were small and far enough apart for a rover to pass between — because dunes have been known to eat Mars rovers,” said Graser. “Perseverance also needed an entrance ramp we could safely travel down. When the imagery showed both, we made a beeline for it.”
The Perseverance science team was also eager to travel through the ancient river channel because they wanted to investigate ancient Martian river processes.
Rock Star
With AutoNav helping guide the way on the channel floor, Perseverance covered the 656 feet (200 meters) to the first science stop in one sol. The target: “Mount Washburn,” a hill covered with intriguing boulders, some of a type never observed before on Mars.
Superimposed on an image from NASA’s Mars Odyssey orbiter, this map shows Perseverance’s path between Jan. 21 and June 11. White dots indicate where the rover stopped after completing a traverse beside Neretva Vallis river channel. The pale blue line indicates the rover’s route inside the channel.NASA/JPL-Caltech/University of Arizona “The diversity of textures and compositions at Mount Washburn was an exciting discovery for the team, as these rocks represent a grab bag of geologic gifts brought down from the crater rim and potentially beyond,” said Brad Garczynski of Western Washington University in Bellingham, the co-lead of the current science campaign.“But among all these different rocks, there was one that really caught our attention.” They nicknamed it “Atoko Point.”
Some 18 inches (45 centimeters) wide and 14 inches (35 centimeters) tall, the speckled, light-toned boulder stands out in a field of darker ones. Analysis by Perseverance’s SuperCam and Mastcam-Z instruments indicates that the rock is composed of the minerals pyroxene and feldspar. In terms of the size, shape, and arrangement of its mineral grains and crystals — and potentially its chemical composition — Atoko Point it is in a league of its own.
Some Perseverance scientists speculate the minerals that make up Atoko Point were produced in a subsurface body of magma that is possibly exposed now on the crater rim. Others on the team wonder if the boulder had been created far beyond the walls of Jezero and transported there by the swift Martian waters eons ago. Either way, the team believes that while Atoko is the first of its kind they’ve seen, it won’t be the last.
After leaving Mount Washburn, the rover headed 433 feet (132 meters) north to investigate the geology of “Tuff Cliff” before making the four-sol, 1,985-foot (605-meter) journey to Bright Angel. Perseverance is currently analyzing a rocky outcrop to assess whether a rock core sample should be collected.
More About the Mission
A key objective for Perseverance’s mission on Mars is astrobiology, including caching samples that may contain signs of ancient microbial life. The rover will characterize the planet’s geology and past climate, pave the way for human exploration of the Red Planet, and be the first mission to collect and cache Martian rock and regolith.
Subsequent NASA missions, in cooperation with ESA (European Space Agency), would send spacecraft to Mars to collect these sealed samples from the surface and return them to Earth for in-depth analysis.
The Mars 2020 Perseverance mission is part of NASA’s Moon to Mars exploration approach, which includes Artemis missions to the Moon that will help prepare for human exploration of the Red Planet.
NASA’s Jet Propulsion Laboratory, which is managed for the agency by Caltech, built and manages operations of the Perseverance rover.
For more about Perseverance:
https://mars.nasa.gov/mars2020/
News Media Contacts
DC Agle
Jet Propulsion Laboratory, Pasadena, Calif.
818-393-9011
agle@jpl.nasa.gov
Karen Fox / Charles Blue
NASA Headquarters, Washington
301-286-6284 / 202-802-5345
karen.c.fox@nasa.gov / charles.e.blue@nasa.gov
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Last Updated Jun 13, 2024 Related Terms
Perseverance (Rover) Jet Propulsion Laboratory Mars Mars 2020 Mars Sample Return (MSR) The Solar System Explore More
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By NASA
2 Min Read Going the Extra 500 miles for Alaskan River Ice
Fresh Eyes on Ice science team from the University of Alaska Fairbanks stop in the Alaska Native village of Shageluk on a community and citizen science journey of 550 mile by snow mobile. Credits:
Photo by Amanda Byrd, UAF Teachers and students in remote Alaskan villages have become vital NASA climate researchers. These special volunteers are so important that last year, climate scientists took an epic 550 mile snowmobile journey to collaborate with them! You can learn all about it in a new video from the Fresh Eyes on Ice project.
The researchers stopped at several remote Alaskan villages, where teachers and students at the local schools already understood why this work was so crucial. When you drive over ice-covered rivers every day—as many Alaskan residents do—tracking ice thickness is no joke. Neither is climate change.
“We knew that climate change was happening around us.” explains Joyanne Hamilton, a teacher whose students worked with the team. “Our elders here in Shageluk were talking about changes that were happening….the data they’re gathering is ultimately important to the tribe.”
The new video features Hamilton, her students, and Fresh Eyes on Ice researchers Dr. Chris Arp, Allen Bondurant and Sarah Clement. It follows their journey along the Innoko, Kukokwim and Yukon Rivers and the Iditarod Sled Dog Trail.
Fresh Eyes on Ice science team from the University of Alaska Fairbanks stop in the Alaska Native village of Shageluk on a community and citizen science journey of 550 mile by snow mobile. Photo by Amanda Byrd, UAF Do you live in Alaska or elsewhere in North America where ice forms? All you need to help out is a smartphone and NASA’s GLOBE Observer Landcover app. Your photos will be used in near-real time by river forecasters to help predict spring ice jam flooding, and by scientists to understand how ice timing and extent is changing. Join Fresh Eyes on Ice here!
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Last Updated Dec 21, 2023 Related Terms
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By USH
An intriguing photograph taken along the banks of the Pilcomayo River in Tarija, Bolivia has ignited a buzz across social media, with speculations swirling about a potentially extraterrestrial being.
Image credit: NOTIVISIÓN
Amid the growing uncertainty and the need for clarity regarding the image's authenticity, NOTIVISIÓN sought the perspective of an expert in UFOlogy. The renowned ufologist, Javier Carlos Cordero, known for his experience in the study of extraterrestrial sightings and phenomena, shared his analysis of the enigmatic image reports news outlet reduno.
Cordero shed light on the possible nature of the mysterious being, stating, "At the edge of the Pilcomayo River, you can observe this figure walking or moving. In the photo, there's a semi-transparent entity with elongated limbs, characteristics that align with what's commonly known as a 'gray being.'"
However, Cordero approached the matter with caution, refraining from hasty conclusions and emphasized the need for a thorough investigation before reaching any verdicts. “ This image must undergo a process of analysis through a filter that determines its authenticity and whether it has been subjected to digital manipulation. Only then can we discern whether we are dealing with genuine evidence or an edited product,” added Cordero, stressing the importance of a rigorous approach.
The Tarija region has seen previous instances of unidentified flying objects and inexplicable entities. The area's abundance of minerals and potential dimensional portals may be linked. The historical context is also significant, including the reevaluation of the Mecoya case from May 6, 1978, involving sightings of craft and similar beings.
Image credit: NOTIVISIÓN
The image of a potential encounter with an extraterrestrial being continues to defy conventional explanation, leaving the community both intrigued and anxious for the conclusions of the ongoing investigation.
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By USH
On June 26, 2023, the owner of a drone managed to capture a perplexing moment near a crop circle in Owlsebury, Hampshire, UK. The drone's camera recorded an unknown orb or sphere flying towards the drone, but it is the question whether this entity has anything to do with the crop circle.
Credit image: Van and Drone Adventures.
This sphere exhibits an appearance reminiscent of energetic phenomena, like a plasma ball, and it moves at high speed before vanishing into thin air.
Given the remarkable velocity of the object and the absence of any discernible flapping wings, it seems unlikely that the entity in question is a mere insect or bird.
It's hard to pinpoint exactly what it was, but its characteristics bear resemblance to what is known as a "Fastwalker." Alternatively, it raises speculation about potentially supernatural origins, such as a manifestation of a soul.
The first video provides a view of the sphere's approach, showing both normal and slow-motion speeds to enable a closer analysis of the strange object. The second video shows the crop circle discovered on June 26, 2023. See images of the crop circle at: http://www.cropcircleconnector.com/2023/allankingway/allankingway2023a.html
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